Lorimer certainly couldn’t imagine that Narkevic’s 2007 analysis would open up a new field in astrophysics that is still mystifying scientists after 10 years.

The upshot: thousands of times each day, an ultra-brief, intense burst of radio waves is generated somewhere in the Universe, and astronomers have frustratingly few clues as to their origin. “There’s still an awful lot of work ahead of us,” observes Lorimer.

The ‘Lorimer burst’ of 24 July 2001 was no freak event. Occasionally, other Parkes observations also caught similar fast radio bursts (FRBs), lasting a few milliseconds at most and occurring randomly in the sky.

Taking the extremely narrow field of view of the radio telescope into account, it was easy to calculate that these mysterious explosions must in fact be very frequent. But what are they, and where do they come from?

If you don’t know the location of an FRB (either within our own Milky Way or far beyond), you can’t deduce the energies of the outburst. It could be a relatively minor explosion on the surface of a nearby dwarf star, or a titanic event at the edge of the observable Universe.

Astronomers had only one clue: all FRBs display a relatively strong ‘dispersion’, which means that lower-frequency waves lag behind higher-frequency ones.

This effect is caused by the waves passing through a tenuous gas of charged particles. High dispersion means lots of intervening particles, corresponding to large distances.

But no one could be completely sure.

Artist's impression of a gamma ray burst, caused by binary neutron stars collapsing into one another. The FRB afterglow is similar to that of gamma ray bursts.

Credit: Franklin and Marshall College

Closing in on the signal

To complicate matters, a single-dish radio telescope like Parkes has a relatively low spatial resolution on the sky, so the locations of the bursts weren’t very precisely known. That made it impossible to carry out follow-up observations with larger telescopes.

On the basis of the Parkes detection, the sky position of FRB 150814 couldn’t be determined to a precision better than some 15 arcminutes (half the width of the full Moon).

But ATCA is an interferometer array with much sharper vision, and in the 0.25º ‘error box’ of FRB 150814, Keane and his colleagues found a slowly fading radio source, located in a galaxy at a distance of six billion lightyears.

The afterglow of FRB 150418 was reminiscent of the afterglow of a short gamma-ray burst, which are the result of neutron star collisions in remote galaxies.

In late February 2016, Keane’s team wrote in Nature that FRBs are most likely one-off catastrophic events, even though they couldn’t be 100 per cent sure about the association between the FRB and the ATCA radio source.

But just a week later, Nature published another paper by Canadian, American and Dutch radio astronomers that came to a very different conclusion.

Using the 305m radio telescope at Arecibo Observatory in Puerto Rico, Paul Scholz of McGill University in Montreal and his colleagues had discovered a repeating fast radio burst: FRB 121102 in Auriga also displayed outbursts in May and June 2015.

So whatever was causing these bursts didn’t destroy its source. As Lorimer says: “It’s basically impossible for a cataclysmic event to produce repeating bursts.”

The colossal Arecibo radio telescope determined that FRBs can repeat.

Credit: iStock

Now, the hunt was really on. If FRB 121102 is repeating every now and then, you can just keep an eye on the suspect part of the sky with a large interferometer to localise a new outburst in real time.

Patience paid off, eventually. In September last year, both the Very Large Array in New Mexico and the European VLBI Network succeeded in tracing down the source of the bursts to a small, inconspicuous dwarf galaxy at a distance of some 2.5 billion lightyears.

“It’s an observational breakthrough,” said NASA astrophysicist and gamma-ray burst expert Neil Gehrels when he learned about the results, just before his untimely death in February 2017.

From the known distance, astronomers could now calculate the burst’s energy – about as much in one millisecond as the Sun pours out in 24 hours.

Others think that the repeating bursts may occur in the accretion disc surrounding the black hole that probably lurks in the dwarf galaxy’s core.

Meanwhile, Lorimer is not so sure that there’s just one type of fast radio burst – after all, FRB 121102 is the only one known to repeat so far. “My guess is that there are multiple classes,” he says.

So yes, there’s still a lot of work to do. Astrophysicists look forward to the inauguration this year of the CHIME radio telescope in Canada, which may detect a few dozen FRBs per day.

Meanwhile, Dutch and South African astronomers are about to deploy the 65cm optical MeerLICHT telescope at the South African Astronomical Observatory in Sutherland, a very promising instrument in the search for the true nature of FRBs.

MeerLICHT will automatically and continuously scan the same region of sky as the South African radio interferometer MeerKAT, some 250km to the north.

As soon as MeerKAT happens to catch a fast radio burst, a possible optical afterglow will be captured by MeerLICHT, enabling detailed follow-up observations.

“No one has ever tried this approach before,” says project manager Steven Bloemen of Radboud University in Nijmegen in the Netherlands. “It may revolutionise the field.”

The peryton problem

Around the time that fast radio bursts were discovered, astronomers also came across a very similar type of millisecond signal, albeit with a much different pulse profile.

They looked very artificial – for instance, they were equally bright at all wavelengths – but their true origin remained unknown for a long time.

Parkes radio astronomers called them perytons, after a mythological creature that is half stag, half bird.

Who knew that being keen for lunch could cause so much trouble?

Credit: iStock

In 2015 the peryton puzzle was evenutally solved. It was found that perytons were generated when the door of the microwave oven in the astronomers’ kitchen was opened prematurely.

No new cosmic riddle: just impatient scientists and technicians on site who believed that their lunch was ready!

Unfortunately, the confusion around perytons did slow down the study of genuine fast radio bursts, says Duncan Lorimer, who described the first FRB in 2007.

“It made it harder to get our research funded.”

Chiming in on FRBs

Why a digital telescope with no moving parts might be the instrument that detects the most FRBs – even though that’s not what it’s designed to do.

CHIME, run by four Canadian institutes, is an all-sky observatory, designed to map the distribution of neutral hydrogen in the early Universe, so its main goal is cosmology.

But given its extremely large field of view, it is expected to detect dozens of relatively bright fast radio bursts per day.

The CHIME telescope consists of four massive metal halfpipes - each is 20m wide and 100m long.

Credit: University of British Columbia

The ‘digital telescope’ has no moving parts at all. It consists of four cylindrical ‘half-pipes’, oriented north to south, and measuring 20x100m.

The telescope’s orientation with respect to the sky changes as a result of Earth’s rotation, which makes it possible to use interferometry to create detailed hydrogen maps.

According to radio astronomer Vicky Kaspi of McGill University in Montreal, CHIME could be an excellent FRB detector, despite observing at lower frequencies than Parkes, Arecibo or the Very Large Array.

This article originally appeared in the June 2017 issue of BBC Sky at Night Magazine.

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